DE10119754B4 - Method and device for storing data packets - Google Patents

Abstract

Method for switching data packets,
the data of a data packet present in a first data transmission format and to be forwarded to a receiver being buffered in a memory (1) which is subdivided into memory blocks (7) of equal size,
wherein the data packet to be forwarded is assigned a descriptor (8) which is generated as a function of the type of the first data transmission format and a data field (14) with a reference to the start addresses of those memory blocks (7) of the memory (1) in which the data of the data packet and a data field (9) which describes the first data transmission format of the data packet to be forwarded to the receiver,
wherein the data of the data packet is buffered using the descriptor (8) in the memory (1) and then converted to at least one data packet having a second data transmission format and forwarded to the receiver.

Description

The The present invention relates to a method and an accordingly configured device for storing message or data packets, which in a specific data transmission format present and in a communication network from a sender to a to transfer the desired recipient or to mediate.

For transmission or switching of messages are used in modern telecommunications networks decomposes the messages into several units or data packets. each This data packets is usually with a header and an information field, which contains the actual message or payload information. In addition, an end field ("trailer") as the conclusion of the be provided respective data packets.

The for the Mediation ("routing") of a data packet Information required is usually in the header field of the respective Contain data packets. An example in a MAC frame ("Medium Access Control") transmitted Ethernet data packet (which hereafter referred to simply as the eMAC data packet is) has z. B. in the header field, the source address ("Source Address") and the destination address ("Destination Address") to be transmitted Message on. The destination address of the data packet is in each node evaluated the corresponding communication network to depend on the best Switching path to the desired receiver to investigate.

One eMAC data packet also includes an IP packet ("Internet Protocol"), with such an IP packet until to 60,000 bytes. In switching nodes of a communication network The problem may be that one is in a specific data packet format Present incoming data packet on the output side on or several data packets of a different data packet format are mapped got to. While an Ethernet switch preferably in local area networks application is found, for example, in more modern broadband ISDN communication networks ("Broadband Integrated Services Digital Network ") an ATM switch ("Asynchronous Transfer Mode ") used. In ATM switching, the ones to be transmitted become Messages in the form of data packets of constant length, so-called ATM cells, transmit, the switch of the ATM cells using identifiers in the cell heads or header fields. A special feature of ATM mediation is the fact that each one ATM cell always includes 53 bytes and consists of a header field of 5 bytes and an information field (payload) of 48 bytes. In a switching node of a communication network, which has both an eMAC or IP interface and an ATM interface, Thus, the problem is the data of an incoming IP packet, which may comprise up to 60,000 bytes, on the output side to the relatively short ATM cells, each of which may comprise only 48 bytes of payload, map.

Out WO 99/65193 is a switch for the transmission of data packets between a variety of local area networks (LAN) known. to Caching the data packets, descriptors are generated, which point to those buffer memories in which the data packets are stored.

From the US 6,148,082 For example, a device for re-multiplexing multiple "transport streams", which may be MPEG-2 transport streams in particular, is disclosed Here, too, descriptors are used for buffering, which include pointers to memory locations.

From the EP 0 752 780 discloses a method and apparatus for transferring data packets from a computer system into a network, which allows data packets to be stored in different memory locations. The information about which parts of a data packet are stored where are stored in descriptors.

In Switching nodes or switching devices, such. B. routers or switches, it is therefore necessary to enter the data of an incoming Cache data packets in a buffer ("buffer"). As for the mediation of data packets in communication networks predominantly in the header fields The routing information of the individual data packets is of importance is usually the header field is processed via a fast data path, while the much more extensive payload of the information field an incoming data packet may require a very large amount of data processing with the aforementioned Caching must be subjected to the picture on the wished output data transmission format to enable.

there basically exists the need for a method or a correspondingly configured device, which makes data packets of different data transmission formats as simple as possible, i.e. with as possible low storage requirements and possible few memory accesses can be stored.

This object is achieved by a method with the features of claim 1 and a device having the features of the claim 18 solved. The subclaims each define preferred and advantageous embodiments of the present invention.

The The invention provides a method and apparatus for switching of data packets ready, with the data, especially the payload data one in a first data transmission format present and to a recipient weiterzululei border data packets in a memory in memory blocks of the same Size divided is to be cached. For every data packet to be saved dependent on of the type of the first data transmission format generates a descriptor that contains a data field with a reference to the starting addresses of those memory blocks of the memory in which the data of the data packet are to be stored, and a data field, which is the first data transfer format of the to the receiver describes data packets to be forwarded. The data of the data package are cached in memory using the descriptor and subsequently on at least one data packet with a second data transmission format implemented and sent to the recipient forwarded.

Of the Descriptor is advantageously preferred from 32 bit data words / data fields built up.

Furthermore The descriptor may include a data field which provides information about the Number of memory blocks occupied by the respective data packet Memory gives. In this regard can an iterator can be used, which on the one hand the number of in total designated by the data packet memory blocks and on the other hand includes a run variable, which during the saving of the respective Data packets are incremented with the respective memory block used becomes.

During the Saving the data of a data packet, each memory block starting at its start address and / or ending at its end address to be discribed. About that but it is also possible that each memory block starting at a certain address offset based on his starting address and / or up to a certain Address offset is described based on its end address. To This purpose can be achieved when saving the data of a data packet used descriptor have a pointer which on the Address of a memory block references, in which actually with to start saving. Likewise, the descriptor can be a Pointer, which on the address of a memory block refers to which actually the Data should be written to the respective memory block.

By Use of the invention proposed Data structure or the descriptor proposed according to the invention may be the processing of the data of the data packet to be stored by be decoupled from the physical storage process. By the Using a memory with memory blocks fixed or identical memory it is ensured that only the total storage capacity of the memory is variable can be reserved, which actually save the respective Data packets needed becomes. Thus, you can easily data packets of different lengths or different Scope are stored in one and the same memory. By use a pointer array is an easier way to process the data and easier addressing of the required memory blocks possible. moreover This makes the release of obsolete storage blocks easier ("Garbage collection").

The The present invention is generally suitable for processing or Storage of data packets of different data transmission formats, such as eMAC, IP, MPLS (Multi Protocol Label Switch) or AAL5 data packets.

Especially It is advantageous if the storage capacity of the individual memory blocks of the memory used to store the data packets have a capacity which correspond to the scope of the information field (payload) of an ATM cell and thus 48 bytes. In this case, the payload of a ATM cell already stored in a single memory block, resulting in the construction of the needed Descriptors significantly simplified.

The Invention is generally suitable for use in all fields of application, where data packets, in particular data packets with different data transmission formats, to be stored, the present invention in particular in telecommunications switching equipment, such. B. in shape from network processors to so-called line cards for switches or routers Use can come. In particular, the present invention suitable for use in telecommunications switching equipment, which over Interfaces for different data transfer formats, such as over an Ethernet, IP, MPLS, or ATM interface the data of one received with a particular data transmission format Data packets to at least one data packet with a different data transmission format to map, which to the desired receiver should be taught.

The The present invention will be explained in more detail below with reference to FIGS Drawing described with reference to preferred embodiments.

1 shows a simplified block diagram of a telecommunications switching device with an inventive device for storing the data of data packets of different data transmission formats,

2 shows a possible structure of a descriptor used for storing an eMAC data packet according to the invention,

3 10 is a diagram for explaining the construction of a descriptor used for storing an ATM cell according to the present invention;

4 shows a diagram for explaining the structure of a descriptor used for storing an AAL5 data packet according to the invention, and

5 shows a diagram for explaining the structure of a descriptor used for storing an MPLS data packet according to the invention.

In 1 is shown in the form of a highly simplified block diagram of the structure of a device according to the invention, as it can be used for example in a router or switch a telecommunications network. An integral part is a cache 1 in which the data is a via a connection unit 3 or 4 received data packets are cached. In the illustrated embodiment, it is assumed that the connection unit 3 an interface to an Ethernet communication network, in particular to a MAC frame Ethernet communication network (eMAC communication network), defined while the connection unit 4 defines an interface to an ATM communication system, ie via the connection unit 3 are data packets according to the eMAC data transmission format and the connection unit 4 Data packets received or sent according to the ATM data transmission format.

The memory access to the memory 1 is from a control unit 2 controlled, the control unit 2 especially responsible for storing the data of an incoming data packet in the memory 2 cached and then transferred to the data transmission format of an outgoing data packet. For this purpose, the control unit communicates 2 with the connection units 3 and 4 via bidirectional data paths 5 , In addition, between the connection units 3 . 4 and the memory 1 a fast bidirectional data path 6 which is used for accelerated and preferred processing of the information contained in the header of a received data packet. As has already been explained, the information contained in the header field of a data packet mainly serves to "routing" the respective data packet to the desired recipient, so that this information is of overriding importance and must therefore preferably be processed in order to determine the suitable switching paths to be able to. The payload contained in the information field of the respective data packet is transmitted by the control unit 2 via access via the data paths 5 essentially unchanged in the memory 1 stored during the information contained in the header of the data packet over the faster data path 6 and the memory 1 after a corresponding data processing by the control unit 2 is forwarded.

When buffering the data of a received data packet, in particular the payload data of a received data packet, is from the control unit 2 uses a special data structure in the form of a descriptor, the basic structure of the descriptor being substantially the same for the different data transmission formats. Nevertheless, the descriptor may slightly differ depending on the data transmission format of the data packet to be stored, that is, depending on the type of the data packet to be stored.

Upon receipt of a data packet to be stored, a special function of the control unit becomes dependent on the type of this data packet 2 activated, by which generates a descriptor suitable for the description of this data packet and the parameters contained in the descriptor are set accordingly. By using the thus generated descriptor then the data of the corresponding data packet from the control unit 2 in the store 1 cached. After processing a received data packet in the manner described above, an update of the descriptor for processing a further data packet of the same type can be undertaken. If no data packet of the same type is available for processing, the descriptor is preferably deleted in order to free up memory space required for storing the descriptors. For example, the descriptors may also be in the memory 1 or directly in the control unit 2 get saved.

The following will be with reference to 2 - 5 Preferred embodiments for the structure of descriptors for describing different data packet types explained.

As in 2 shown is the memory 1 , which is provided for temporarily storing the data of a data packet, in a plurality of equal-sized memory blocks 7 divided. Likewise is in 2 a possible structure for a descriptor 8th to describe an eMAC data packet. With the help of the descriptor, the connection or association between the data of the data packet to be stored and the memory blocks required for storing these data 7 of the memory 1 produced.

The in 2 Descriptor shown 8th includes a data field or data word 9 , which designates the type of the respective data packet, in the present case the type "eMAC". The data word 9 In addition, it may also contain information which provides information about the extent of the data to be stored or the data packet size, it being possible, for example, to distinguish between two different data packet sizes. This information may be used for the block-wise reservation or release of the memory 1 to be helpful.

Another data word 10 the descriptor 8th can optionally be assigned or used depending on the type of the respective data packet (for example, for storing header information). In the case of an eMAC data packet, the data word is 10 in the present case, with no information.

In addition, the descriptor includes 8th a data word 11 which comprises an iterator with a parameter L and a variable K. The parameter L denotes the number of memory blocks 7 which are needed in total for storing the data of the respective data packet. On the other hand, the run variable K denotes the memory block currently used for storage 7 ie, the run variable K becomes every memory block change 7 changed or incremented. Depending on the value of the parameter L, the required number of memory blocks 7 reserved.

An essential part of the preferably 32-bit-organized descriptor 8th is a data field 14 in which a pointer array with pointers or pointers to the starting addresses of the L required memory blocks 7 is stored. In the data field 14 There is thus a list of pointers to the starting addresses of those memory blocks 7 referenced, which are needed to save the respective data packet. The data field 14 includes according to the value of the data field 11 contained parameter L thus L different pointers.

When storing the data of a data packet, these can be generated using the descriptor shown 8th successively starting at the start address of the first memory block 7 into the individual memory blocks 7 be written, with the memory blocks 7 each fully described. Instead, however, it is also possible to start the data starting with a certain address offset OFF1 relative to the start address of the first memory block 7 up to a certain address offset OFF2 relative to the end address of the last memory block 7 enroll. For this purpose, the includes in 2 illustrated descriptor 8th a data field 12 with a reference to the address of the first memory block 7 in which, in fact, the writing of the data is to be started so that the data in the data field 12 contained information can also be referred to as a start pointer or S pointer. Accordingly, the descriptor includes 8th at the in 2 illustrated embodiment, a data field 13 with a reference to the address of the last memory block 7 to which the data is actually stored in memory 1 should be written, so that in the data field 13 contained information can also be referred to as a trail pointer or T-pointer. The through the data field 12 Thus, the described S-pointer defines the address offset OFF1 while passing through the data field 13 described T-pointer the address offset OFF2 defined. Of course, it is also conceivable that the S pointer and the T pointer not on the first and last memory block 7 of the memory 1 but are common to one and the same memory block 7 refer so that when storing the data of a data packet, the data in the individual memory blocks 7 always be written with an offset OFF1 or an offset OFF2.

In the 2 shown structure of the descriptor 8th For example, it is also useful for storing an Ethernet CPCS (Common Part Convergence Sublayer) data packet. This is an intermediate format which is used, for example, for ATM segmentation.

The size of each memory block 7 the memory used to buffer the data 1 is not fixed in principle. In particular, it is also conceivable that each memory block 7 again associated with a plurality of memory elements of smaller size. However, it is particularly advantageous if the memory blocks 7 have a storage capacity sufficient to store the smallest possible data packet type. So can the storage capacity of the memory blocks 7 For example, be chosen such that each memory block 7 completely store the data of an ATM cell (53 bytes) or at least the payload data of an ATM cell (48 bytes), since ATM cells are the shortest data packets, which always have the same structure.

Is the storage capacity of each memory block 7 selected to 48 bytes, can be used to describe an ATM cell or an ATM data packages a descriptor 8th to be used with a particularly simple structure, as in 3 is shown. The in 3 Descriptor shown 8th again comprises a data word 9 (which, for example, may comprise 32 bits analogous to the other described embodiments) to describe the type of the respective data packet. In addition, the data field 14 which according to 2 is reduced to a single pointer, which reduces to the starting address of the memory block required to store the corresponding ATM cell 7 refers because of the size of the memory blocks selected 7 already a memory block is sufficient for storing the payload data of a whole ATM cell. In addition, according to 3 the data field 10 the descriptor 8th occupied with the header contained in the header of the respective ATM cell information. The separate storage of the header information of the ATM cell in the descriptor 8th makes sense, since this information - as has already been described - for the switching of the ATM cell is of primary importance. Of course, that can be done in 3 illustrated embodiment, however, are also modified such that the memory block 7 53 bytes, so in the memory block 7 both the header data and the payload data of a single ATM cell can be stored, in which case the data field 10 can remain unused. The recognition of the correct format of the descriptor takes place via the data field 9 which designates the type.

In an ATM-based communication network transmission and switching the ATM cells basically independently from the respective application. The required flexibility of ATM communication networks in terms of different communication processes, such as audio, Video or data communication results from the functionality of a special ATM adaptation layer, which is called an AAL layer. The functions of the AAL layer are relative to the bit rate (constant or variable), the type of communication (connection-oriented or connectionless) etc. depending on the application. Regardless of the function of the AAL layer is differentiated between different service classes or AAL types. The service class AAL5 supports for example, the for Data communication typical VBR traffic ("variable bitrate"), with both connectionless as Connection-oriented communication is also possible.

In practice, for example, for the connectionless case, AAL5 data transmission is used for ATM communication between local area networks ("LANs"), the AAL5 class of service and the AAL5 service type being used in particular for the division of the data an IP packet to multiple ATM cells is suitable. In this application, it is typical that the ATM cells assigned to an IP packet all have the same header field, with only the last ATM cell having a different header field. Consequently, for this scenario, for example, a descriptor 8th with the in 4 shown construction, wherein the data word 9 describes the type "AAL5". The according to 2 optionally used data field 10 is at the in 4 divided embodiment shown and described on the one hand, the header field of the last ATM cell (header 2) and on the other hand, the header field of all other ATM cells (header 1). The data fields or data words 11 - 14 are analogous to 2 busy. It is advantageous that only one descriptor 8th for all ATM cells that are assigned to an AAL5 frame or an AAL5 CPCS frame can be used.

In 5 is a possible construction of the descriptor 8th for describing an MPLS data packet ("Multi Protocol Lable Switching"). MPLS integrates IP and ATM by combining Layer 2 functionality (ATM switching) with Layer 3 functionality (IP routing). For this purpose, an MPLS data packet comprises an IP data packet, which is provided with a special 32-bit header field, which is called a "shim header". This "Shim Header" includes a 20-bit label, which is used for switching ("routing" / "switching") of the corresponding data packet (in contrast, only the destination address ("Destination Address") is evaluated in a pure IP switching For example, bits of the "Shim Header" denote the quality of service, ie, for example, whether important video data or less important audio data is transmitted, etc.

The IP packet contained in an MPLS data packet is normal IP protocol established.

To describe such an MPLS data packet, the in 5 Descriptor shown 8th again a data field or data word 9 , which denotes the type of the data packet. The data field 10 is occupied in the illustrated embodiment with the information of the header field described above ("Shim Header"). The data fields 11 - 14 are analogous to those in 2 and 4 illustrated embodiments, so that reference may be made in this regard to the preceding explanations.

Claims (20)

A method of switching data packets, wherein the data is one of a first data transmission format and a receiver forwarded data packets in a memory ( 1 ) stored in memory blocks ( 7 ) are cached, wherein the data packet to be forwarded, a descriptor ( 8th ), which is generated depending on the type of the first data transmission format and a data field ( 14 ) with a reference to the starting addresses of those memory blocks ( 7 ) of the memory ( 1 ), in which the data of the data packet are to be stored, and a data field ( 9 ), which describes the first data transmission format of the data packet to be forwarded to the receiver, the data of the data packet being written using the descriptor ( 8th ) in the memory ( 1 ) and then converted to at least one data packet with a second data transmission format and forwarded to the receiver. Method according to claim 1, characterized in that the descriptor ( 8th ) a data field ( 12 comprising an address offset (OFF1) with respect to the start address of a memory block ( 7 ), in which the data of the data packet is to be stored, describes, wherein the data of the data packet beginning at this address offset (OFF1) in the corresponding memory block ( 7 ) to be written. Method according to claim 1 or 2, characterized in that the descriptor ( 8th ) a data field ( 13 comprising an address offset (OFF2) with respect to the end address of a memory block ( 7 ), in which the data of the data packet is to be written, describes, whereby the data of the data packet into the appropriate memory block ( 7 ) are written to this address offset (OFF2). Method according to one of the preceding claims, characterized in that the descriptor ( 8th ) a data field ( 11 ), which on the one hand reduces the number (L) of memory blocks required for storing the data of the data packet ( 7 ) of the memory ( 1 ) and, on the other hand, has a variable (K) which, during the storage of the data, is stored with each memory block (K). 7 ) of the memory ( 1 ) is changed and thus each of the currently described memory block ( 7 ) of the memory ( 1 ) designated. Method according to one of the preceding claims, characterized in that the data packet to be forwarded comprises a header field and an information field, which has payload data, wherein with the aid of the descriptor the payload data contained in the information field is stored in the memory ( 1 ) get saved. Method according to one of the preceding claims, characterized in that the first data transmission format is an Ethernet data transmission format is. Method according to one of the preceding claims, characterized in that the first data transmission format is an Ethernet CPCS data transmission format is. Method according to one of the preceding claims, characterized in that the first data transmission format is an ATM data transmission format is. Method according to one of the preceding claims, characterized in that the memory blocks ( 7 ) of the memory ( 1 ) each have a storage capacity sufficient to store data of a data packet present in an ATM data transmission format. Method according to Claim 9, characterized in that the memory blocks ( 7 ) of the memory ( 1 ) each have a storage capacity of 48 bytes in order to be able to completely store the payload data contained in an information field of the data packet present in the ATM data transmission format. A method according to claim 8 and claim 9 or 10, characterized in that the to the starting addresses of the required memory blocks ( 7 ) of the memory ( 1 ) referring data field ( 14 ) of the descriptor ( 8th ) for the data packet present in the ATM data transmission format only a reference to the start address of a single specific memory block ( 7 ) of the memory ( 1 ) having. Method according to claims 10 and 11, characterized in that by using the address of the start of the particular memory block ( 7 ) referring data field ( 14 ) of the Descrip gate ( 8th ) the user data contained in the information field of the data packet present in the ATM data transmission format in the particular memory block ( 7 ) and that the descriptor ( 8th ) for the data packet present in the ATM data transmission format, a data field ( 10 ) for designating the data contained in the header field of the data packet. Method according to one of the preceding claims, characterized in that the first data transmission format is an AAL5 data transmission format is. Method according to claim 13, characterized in that in that the data of a data packet present in an IP data transmission format is mapped to a plurality of data packets in an ATM data transmission format using the AAL5 data transmission format, wherein each data packet present in the ATM data transmission format comprises a header field and an information field having payload data, and the Descriptor ( 8th ) for the AAL5 data transmission format a data field ( 10 ) for designating the header field of the most recent data packet present in the ATM data transmission format and the header field of all other data packets present in the ATM data transmission format. Method according to one of the preceding claims, characterized in that the first data transmission format is an MPLS data transmission format is. Method according to one of the preceding claims, characterized in that the data packet to be forwarded to the receiver has a header field and an information field with user data, and that the user data contained in the information field is stored in the memory ( 1 ) using the descriptor ( 8th ), the descriptor ( 8th ) a data field ( 10 ) for describing the header field of the respective data packet. Method according to one of the preceding claims, characterized characterized in that the second data transmission format is different to the first data transmission format is. Device for switching data packets, wherein a data packet to be forwarded to a receiver is present in a first data transmission format, having a memory ( 1 ), which is divided into a plurality of memory blocks ( 7 ) of equal size, and with a control device ( 2 ) for generating a descriptor ( 8th ) associated with the data packet to be forwarded, depending on the type of the first data transmission format, the descriptor ( 8th ) a data field ( 14 ), which is based on the starting addresses of the memory blocks required for storing the data of the data packet ( 7 ) of the memory ( 1 ), and where the descriptor ( 8th ) a data field ( 9 ), which describes the first data transmission format of the data packet to be forwarded to the receiver, wherein the control device ( 2 ) for caching the data packet data using the descriptor ( 8th ) in the memory ( 1 ) and for the subsequent conversion of the cached data to at least one data packet with a second data transmission format is configured to forward the at least one data packet with the second data transmission format to the receiver. Device according to claim 18, characterized in that that the device is part of a telecommunications switching device is. Device according to claim 18 or 19, characterized that the device is carrying the method according to any one of claims 1-17 is configured.